Structural Studies of Mixed Glass Former 0.35Na2O + 0.65[xB2O3 + (1 – x)P2O5] Glasses by Raman and 11B and 31P Magic Angle Spinning Nuclear Magnetic Resonance Spectroscopies

Christensen, Randilynn; Olson, Garrett; Martin, Steve W.

doi:10.1021/jp308494a

Cited by 53 publications

(66 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…On the one hand the 31 P NMR data clearly indicate that the germanate network is partially modified for x ≥ 0.4, on the other hand, neither Raman spectroscopy nor XPS provide any clear evidence for the formation of nonbridging oxygen atoms associated with depolymerized Ge (3) or Ge (2) units, except for the x ≥ 0.8 samples. Thus, the conclusion appears inescapable that germanate modification proceeds (at least partially) by the formation of higher-coordinated germanium Ge (5) and/or Ge (6) units in this glass system. This conclusion is consistent with recent neutron diffraction data by Hoppe et al on gemanophosphate glasses with similar compositions.…”

Section: (mentioning

confidence: 92%

“…Ge (5) and Ge (6) units (with bond valences of 0.8 and 0.67) may be stabilized by interaction with P (3) units (bond valence 1. 25), and this interaction may contribute to the preference for heteroatomic P−O−Ge linkages in this glass system, as it is found experimentally.…”

Section: (mentioning

confidence: 99%

“…Figure 11 shows this plot for the KGeP{Yb} and NaGeP{Eu} glasses. Again, the concentrations attributed there to the concentrations of Ge (3) units actually comprise the total inventory of anionic Ge (3) , Ge (5) , and Ge (6) units. The results underline that the observed behavior is the same for both network modifier cations.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M₂O)_1/3[(Ge₂O₄)_x(P₂O₅)_1–x]_2/3

Behrends

Eckert

2014

J. Phys. Chem. C

View full text Add to dashboard Cite

The structure of mixed-network former glasses in the system (M2O)0.33[(Ge2O4) x (P2O5)1–x ]0.67.(M = Na, K) has been studied by 31P and 23Na high-resolution and dipolar solid state nuclear magnetic resonance (NMR) techniques, O-1s X-ray photoelectron spectroscopy, and Raman spectroscopy. Using an iterative fitting procedure, a quantitative structural model has been developed that is consistent with all of the experimental data and which provides a detailed description of network connectivities, network modification processes, and spatial cation distributions. Formation of heteroatomic P–O–Ge linkages is generally preferred over homoatomic P–O–P and Ge–O–Ge linkages, as shown by a detailed comparison with a random linkage model. An exception occurs in glasses with low germanium contents (x = 0.2) where a pronounced nonlinear dependence of the glass transition temperature on x can be related to a cross-linking of the sodium ultraphosphate network by fully polymerized germanium species, possibly including also 5- and 6-fold coordination states. At higher x values, the Ge component is modified as well, however, the fraction of anionic nonbridging oxygen atoms bound to germanium is always lower than expected for proportional modifier sharing between both network formers. Rather, the phosphate component is preferentially modified by the cations, leading to the formation of P(1) units at high x values. Consequently, the local coordination of the cations is dominated by phosphorus, as is clearly evident from the 23Na{31P} rotational echo double resonance (REDOR) results. This preferred association, combined with the formation of P(1) units, results in partially clustered cation distributions, which can be detected by 23Na spin echo decay spectroscopy. Finally, the joint interpretation of all of the data from NMR, Raman, XPS, and thermal analysis measurements offers indirect evidence for the formation of higher germanium coordination states in this glass system.

show abstract

Section: (mentioning

confidence: 92%

Section: (mentioning

confidence: 99%

See 1 more Smart Citation

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M₂O)_1/3[(Ge₂O₄)_x(P₂O₅)_1–x]_2/3

Behrends

Eckert

2014

J. Phys. Chem. C

View full text Add to dashboard Cite

show abstract

“…At x = 0.4, B 4 makes up 37% of the SRO structural units and at x = 0.5 B 4 makes up 40% of the SRO structural units according to our previously reported NMR data. 51 However, at x = 0.4 and 0.5, phosphorus units make up 60 and 50% of the SRO units. The NMR data indicate that the number of B P 4 is greater than the B B 4 until x = 0.4, after which B B 4 is the dominant boron tetrahedral unit.…”

Section: +mentioning

confidence: 99%

Ionic Conductivity of Mixed Glass Former 0.35Na₂O + 0.65[xB₂O₃ + (1 – x)P₂O₅] Glasses

2013

Self Cite

View full text Add to dashboard Cite

The mixed glass former effect (MGFE) is defined as a nonlinear and nonadditive change in the ionic conductivity with changing glass former fraction at constant modifier composition between two binary glass forming compositions. In this study, mixed glass former (MGF) sodium borophosphate glasses, 0.35Na 2 O + 0.65[xB 2 O 3 + (1 -x)P 2 O 5 ], 0 ≤ x ≤ 1, have been prepared, and their sodium ionic conductivity has been studied. The ionic conductivity exhibits a strong, positive MGFE that is caused by a corresponding strongly negative nonlinear, nonadditive change in the conductivity activation energy with changing glass former content, x. We describe a successful model of the MGFE in the conductivity activation energy terms of the underlying short-range order (SRO) phosphate and borate glass former structures present in these glasses. To do this, we have developed a modified Anderson-Stuart (A-S) model to explain the decrease in the activation energy in terms of the atomic level composition dependence (x) of the borate and phosphate SRO structural groups, the Na + ion concentration, and the Na + mobility. In our revision of the A-S model, we carefully improve the treatment of the cation jump distance and incorporate an effective Madelung constant to account for many body coulomb potential effects. Using our model, we are able to accurately reproduce the composition dependence of the activation energy with a single adjustable parameter, the effective Madelung constant, that changes systematically with composition, x, and varies by no more than 10% from values typical of oxide ceramics. Our model suggests that the decreasing columbic binding energies that govern the concentration of the mobile cations are sufficiently strong in these glasses to overcome the increasing volumetric strain energies (mobility) caused by strongly increasing glass-transition temperatures combined with strongly decreasing molar volumes of these glasses. The dependence of the columbic binding energy term on the relative high-frequency dielectric permittivity suggests that the increased polarizability of the bridging oxygens connecting SRO tetrahedral boron units to phosphorus units causes further charge delocalization away from the negatively charged tetrahedral boron units, leading to a lowering of the charge density, and is the underlying cause of the MGFE. Disciplines Materials Science and Engineering CommentsReprinted with permission from Journal of Physical Chemistry B 117 (2013) , 0 ≤ x ≤ 1, have been prepared, and their sodium ionic conductivity has been studied. The ionic conductivity exhibits a strong, positive MGFE that is caused by a corresponding strongly negative nonlinear, nonadditive change in the conductivity activation energy with changing glass former content, x. We describe a successful model of the MGFE in the conductivity activation energy terms of the underlying short-range order (SRO) phosphate and borate glass former structures present in these glasses. To do this, we have developed a modified Anderson-Stuart (...

show abstract

“…Advanced NMR methods, together with O-1s X-ray photoelectron spectroscopy have furnished important information regarding this issue in a number of boroncontaining glasses [11,[26][27][28][29][30][31][32][33]. For example, the strongly non-linear compositional dependences of glass transition temperatures and ionic conductivities observed in alkali borophosphate glasses could be explained satisfactorily on a structural basis, using 11 B and 31 P single and double resonance NMR techniques [28][29][30][31][32][33]. These glasses are characterized by a very exothermic interaction between the two different network formers, resulting in nearly maximized numbers of B-O-P linkages [30].…”

Section: Introductionmentioning

confidence: 99%

Mixed network former effects in tellurite glass systems: Structure/property correlations in the system (Na2O)1/3[(2TeO2)x(B2O3)1−x]2/3

Larink

Eckert

2015

Journal of Non-Crystalline Solids

View full text Add to dashboard Cite

Structural Studies of Mixed Glass Former 0.35Na₂O + 0.65[xB₂O₃ + (1 – x)P₂O₅] Glasses by Raman and ¹¹B and ³¹P Magic Angle Spinning Nuclear Magnetic Resonance Spectroscopies

Cited by 53 publications

References 40 publications

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M₂O)_1/3[(Ge₂O₄)_x(P₂O₅)_1–x]_2/3

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M₂O)_1/3[(Ge₂O₄)_x(P₂O₅)_1–x]_2/3

Ionic Conductivity of Mixed Glass Former 0.35Na₂O + 0.65[xB₂O₃ + (1 – x)P₂O₅] Glasses

Mixed network former effects in tellurite glass systems: Structure/property correlations in the system (Na2O)1/3[(2TeO2)x(B2O3)1−x]2/3

Contact Info

Product

Resources

About

Structural Studies of Mixed Glass Former 0.35Na2O + 0.65[xB2O3 + (1 – x)P2O5] Glasses by Raman and 11B and 31P Magic Angle Spinning Nuclear Magnetic Resonance Spectroscopies

Cited by 53 publications

References 40 publications

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M2O)1/3[(Ge2O4)x(P2O5)1–x]2/3

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M2O)1/3[(Ge2O4)x(P2O5)1–x]2/3

Ionic Conductivity of Mixed Glass Former 0.35Na2O + 0.65[xB2O3 + (1 – x)P2O5] Glasses

Mixed network former effects in tellurite glass systems: Structure/property correlations in the system (Na2O)1/3[(2TeO2)x(B2O3)1−x]2/3

Contact Info

Product

Resources

About

Structural Studies of Mixed Glass Former 0.35Na₂O + 0.65[xB₂O₃ + (1 – x)P₂O₅] Glasses by Raman and ¹¹B and ³¹P Magic Angle Spinning Nuclear Magnetic Resonance Spectroscopies

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M₂O)_1/3[(Ge₂O₄)_x(P₂O₅)_1–x]_2/3

Mixed Network Former Effects in Oxide Glasses: Spectroscopic Studies in the System (M₂O)_1/3[(Ge₂O₄)_x(P₂O₅)_1–x]_2/3

Ionic Conductivity of Mixed Glass Former 0.35Na₂O + 0.65[xB₂O₃ + (1 – x)P₂O₅] Glasses